Glyceryl trimontanate

ABSTRACT

A composition, glyceryl trimontanate is of the class of esters of montanic acid and has the following structural formula: WHEREIN R is a linearly saturated hydrocarbon chain having 24 to 32 carbon atoms. Glyceryl trimontanate is formed by esterifying montanic acid with glycerol. Glyceryl trimontanate has excellent lubricating properties which are displayed upon its addition as an auxiliary agent to the reactive mixture for a synthetic plastic material; the resultant synthetic material is more easily formed such as by extrusion, and has improved shock resistance and transparency.

United States Patent Boussely 1 Sept. 12,1972

[73] Assignee: Societe Sapchim-Fournier-Cimag,

Paris, France 221 Filed: May 4,1970

21 Appl. No.: 34,642

Jean Boussely, Paris, France [30] Foreign Application Priority Data May 7, 1969 France ..6914546 [52] US. Cl ..260/410.7, 260/316 [51] Int. Cl ..Cllc 3/02, C08k l/36 [58] Field of Search ..260/410.7

[56] References Cited UNITED STATES PATENTS 1,737,975 12/1929 Pungs ..260/410.7 X

FOREIGN PATENTS OR APPLICATIONS 764,617 12/1956 Great Britain 244,786 4/1912 Germany OTHER PUBLICATIONS Markley, Fatty Acids, 2nd ed. part 2, lnterscience Publishers, New York (1961) pp. 801- 805 Bailey, lndustrial Oil and Fat Products, 3rd ed. Interscience Publishers, New York, 1964, pp 94 1- 943 Primary Examiner-Lewis Gotts Assistant Examiner-Diana G. Rivers Attorney-Young & Thompson [5 7] ABSTRACT A composition, glyceryl trimontanate is of the class of esters of montanic acid and has the following structural formula:

wherein R is a linearly saturated hydrocarbon chain having 24 to 32 carbon atoms. Glyceryl trimontanate is formed by esterifying montanic acid with glycerol.

Glyceryl trimontanate has excellent lubricating properties which are displayed upon its addition as an auxiliary agent to the reactive mixture for a synthetic plastic material; the resultant synthetic material is more easily formed such as by extrusion, and has improved shock resistance and transparency.

2 Claims, No Drawings GLYCERYL TRIMONTANATE The present invention concerns a new industrial product, glyceryl trimontanate which corresponds to the following general formula:

in which R represents a linearly saturated hydrocarbon chain having 28 carbon atoms and includes products in which the linearly saturated hydrocarbon chain includes 24 to 32 carbon atoms.

The present invention also concerns a process for the preparation of glyceryl trimontanate.

This process comprises, in a general manner, esterifying montanic acid with glyceryl.

Preferably, this esterification corresponds to the following reaction equation This reaction is carried out directly without any solvant and at a temperature taking account of the pressure so that the water formed is water vapor. The reaction can thus be nearly if not totally carried to completion by the continuous shifting of the balance of the reaction in favor of the formation of the glyceryl trimontanate.

Moreover, in a general manner the kinetics of the reaction can be controlled by the quantity of distilled water as well as by the variation of certain common characteristics of any medium such as the acid number and/or the hydroxyl number.

Preferably, the esterification is carried out in the presence of a catalyst which will speed up the reaction. This catalyst may be an acid catalyst, such as [3- naphthalene sulfonic acid an alkaline catalyst, such as sodium or sodium methylate a metallic catalyst, such as zinc powder or any other suitable catalyst.

In practice the quantity of the catalyst which is used is very small with regard to a catalyst soluble in glyceryl trimontanate, such a catalyst can remain in the final product without in any way affecting the characteristics of the final product other than possibly its color and with regard to an alkaline catalyst, its acid number. However, with regard to a catalyst which is insoluble in glyceryl trimontanate such as zinc powder, such a catalyst has to be removed from the final product by filtration.

PREPARATION EXAMPLES Primary materials.

montanic acid glycerol acid number (A.No.) l4l saponification number (S.No.) 150 melting point (m.p.) ash nil Similarly, the glyceryl used had the following characteristics molecular weight (mol.wt.) 92.09

refractive index (at 20 C.) 1.4729

density (at 20 C.) 1.260

boiling point 290 C.

Catalyst used 0.43 grams of commercially available ,B-naphthasul fonic acid was used as the catalysts and has the following characteristics:

molecular weight (mol. wt.) melting point (m.p.)

Mode of preparation The glycerol is placed in an apparatus capable of being placed under a vacuum.

The montanic acid is added and then the B- naphthalene sulfonic acid.

Air is then removed from the apparatus as a current of nitrogen is circulated therein. Nitrogen or any other inert atmosphere is circulated herein in order to avoid any possible oxidation of the reactive medium which could give an undesirable color to the final product. The circulation of the nitrogen is continued until the apparatus is under vacuum as described hereinafter.

The reactive medium is kept in motion and is maintained for 5 hours at 200 C by the heat of the oil bath of the apparatus. The reactive medium become homogeneous towards 90 C and from l40 C the water is collected.

By means of a vacuum pump the pressure in the apparatus is dropped to approximately 5 millibars in 0.25 hours.

At this pressure, the temperature is raised to 220 C in 1 hour while continuing to collect the distilled water. The pressure is so maintained until the acid number of the reactive medium is less than 10 or preferably near 7 which requires approximately 3 hours.

The reaction is then nearly complete.

The ester thus formed is cooled to C. The vacuum is stopped in the apparatus and the cooling is of the ester continued until the temperature reaches 1 l0l00 C.

The ester in question, glyceryl trimontanate, is in the form of a syrup.

The syrup at 100 C is run across a glass plate in order to obtain a solid layer having a thickness of several millimeters.

This solid layer is broken up and the fragments are ground forming a powder which is then sifted.

Results With 100 yield, 410 grams of glyceryl trimon tanate are obtained having the following characteristics acid number (A.No.) 8.1

saponification number (S.No.) 148.5 ester number 136.5 hydroxyl number (OH.No.) 12.4 melting point (m.p.) 77 C. molecular weight (mol.wt.) 1280-1290 OTHER MODES OF PREPARATION Other modes of preparing glyceryl trimontanate have been carried out in which the B-naphthalene sulfonic acid has been substituted by one of the following catalysts, given with the corresponding quantity of which was used sodium .43 g sodium methylate .43 g zinc powder .86 g zinc oxide powder .86 g

The mode of operation remains the same and the results obtained comparable to those indicated above.

Other suitable catalysts could of course be used.

The follow table gives other examples of preparation carried out starting with montanic acid from various sources.

In column A of the table is indicated the nature and quantity in grams of the reactants used in column B the characteristics of the montanic acid used and in column C the characteristics of the glyceryl montanate obtained.

Ex. No A B C montanic acid 393.0 A.No. 141 A.No. 8.] 1 glycerol 29.6 S.No. 150 S.No. 148.5

paratoluenesulfonic acid 0.4 OH.No. 20 OH.No. 12.4 montanic acid 280.0 A.No. 150 A.No. 10.1 11 glycerol 23.0 S.No. 163.5 S.No. 155.

caustic soda lye (50%) 0.6 OH.No. 20 OH.No. 14.5 montanic acid 367.0 A.No. 153 A.No. 9.2 111 glycerol 29.7 S.No. 164 S.No. 148

paratoluene sulfonic 0.4 OH.No. l6 OH.No. l4 montanic acid 359.0 A.No. 1S6 A.No. 10.4 1V glycerol 29.6 S.No. 160 S.No. 150

caustic soda EDD50 0.8 OH.No. 15 OH.No. l3 montanic acid 260.0 A.No. 158 A.No. 9.7 V glycerol 22.0

S.No. 173.5 S.No. 150

caustic soda lye (50 0.56 OH.No. 27 s OXONolS It will be noted that in all the eases the hydroxyl number of glyceryl trimontanate obtained in accordance with the process according to the invention is between and 15, and the saponification number is relatively high.

In all the cases the final product obtained can if necessary be bleached for example by an oxidizing agent, such as sodium chlorite, or hydrogen peroxide used in small amounts, or by a bleaching agent such as decolorizing carbon or active carbon.

APPLICATIONS Glyceryl trimontanate exhibits remarkable properties as an auxiliary agent for masses of synthetic material which are to be formed by molding, extrusion or extrusion-blowing in particular the following synthetic materials polyvinyl chloride, vinyl copolymers, polystyrene, acrylic resins, methacrylic resins, acrylonitrile-butadiene-styrene (AB5), Polyethylene, polypropylene or any other synthetic material.

Firstly, insofar as known, it is necessary to add a lubricating agent to the masses of synthetic material in order to retard as long as possible the sticking to the surfaces of the means in which the material is formed.

It is known to use higher acid esters of polyalcohols such as glyceryl trihydroxy stearate.

Glyceryl trimontanate according to the invention has remarkable qualities as a lubricating agent, far superior to those of lubricating agents already known as is illustrated by the various tests which follow. These tests were all conducted under the same conditions and consisted of recording the time that it took for a sheet of synthetic material passed between cylinders heated to 210 C to begin to stick to the cylinders:

TEST 1 Composition of the sheet P. V. C.

Auxiliary agent (adjuvant) 8 Epoxy oil 2 a-phenylindole 0.6 Glyceryl trihydroxy stearate 2 Result The sheet began to stick at the end of 2 minutes.

TEST 1! omposition of the sheet P.V.C.

Auxiliary agent (adjuvant) Epoxy Oil a-phenylindole Glyceryl trimontanate Glyceryl trihydroxy stearate Result The sheet began to stick at the end of 12 minutes.

TEST lIl Composition of the sheet P.V.C.

Auxiliary agent (adjuvant) 8 Epoxy oil 2 a-phenylindole .8 Glyceryl trimontante 1 Glyceryl trihydroxy stearate 1 Result The sheet began to stick at the end of 20 minutes.

It should be noted that the percentage of a-phenylindole was only increased in order to extend the length of time of thermal stability.

TEST IV Composition of the sheet P.V.C. Auxiliary agent (adjuvant) Epoxy oil a-phenylindole Glyceryl trimontante Result 2 The sheet began to stick at the end of 25 minutes.

PO -NW TEST V Composition of the sheet P.V.C. I00 Auxiliary agent (adjuvant) 8 Thio-organic tin compound l.5 Glyceryl trihydroxyl stearate 2 Result The sheet began to stick at the end of 3 minutes.

TEST VI Composition of the sheet P.V.C.

Auxiliary agent (adjuvant) Thio-organic tin compound Glyceryl trihydroxy stearate Glyceryl trimontanate Result The sheet began to stick at the end of IO minutes.

TEST Vll Composition of the sheet P.V.C. 100 Auxiliary agent (adjuvant) 8 Thio-organic tin compound 1.5 Glyceryl trihydroxy stearate l Glyceryl trimontanate l Result The sheet began to stick at the end of IS minutes.

TEST VIII Composition of the sheet P.V.C. IOO Auxiliary agent (adjuvant) 8 Thio-organic tin compound l.5 Glyceryl trimontanate 2 Result The sheet began to stick at the end of 25 minutes.

The result of Tests V-VIII are comparable to those of the preceding tests l-V.

Other test have also been carried out in replacing the glyceryl trihydroxy stearate by one or the other of the esters formed by reacting a polyalcohol such as mono-, di-, or tri-ethylene glycol, monoor di-propylene glycol, butanediol, trimethylolpropane, glucoses, saccharoses, pentaor di-pentaerythritol with a higher acid comprising more than 10 atoms of carbon with or without double bonds, with or without hydroxyl functions, such as the following acids: lauric, myristic, palmitic, stearic, oleic, linoleic, linolenic, belinic, behenic, phloionic, vaccenic and others. The time in which the sheet began to stick was the same ashereinabove indicated.

In all the cases the lubricating action of the glyceryl trimontanate was not altered, while, the lubricating action of the ester was substantially improved.

In practice, the mixture of the glyceryl trimontanate and the other ester can vary between great limits between 15 percent of glyceryl trimontanate by weight with respect to the total mixture.

Other tests have also been a carried out in which the polyvinyl chloride was replaced by vinyl copolymers of polystyrene, acrilic resins, metacrylic resins, acronitryle-butadiene-styrene, polyethylene and polypropylene.

These tests all confirmed excellent lubricating, antisticking and anti-friction qualities of glyceryl trimontanate. Further, as this factor is particularly important relative to the speed at which material can be extruded, the presence of glyceryl trimontanate permits such plastic material to be extruded at a substantially increased speed without sticking.

The fact that glyceryl trimontanate obtained according to the invention has a lower hydroxylnumber is considered to enhance it excellent lubricating quality.

In all the tests described in detail hereinabove, the presence of an auxiliary agent or adjuvant in the composition tested is noted. Such a product is introduced in a known manner into the mixture in order to modify the polymerization structure and thereby improve the physical characteristics of the final product, and particularly as regards to shock resistance. For example with regard to a'mixture having a polyvinyl chloride base, such as explained more particularly hereinabove, such an auxiliary agent could for example be an acrylic or derivative acronitryle-butadiene-styrene.

Further, the tests described hereinabove' have shown that glyceryl trimontanate,- i.e., relative to the second important property of this product, has a tendancy when it is in such a mixture to improve the distribution and the compatibility in the polycondensation. medium of the auxiliary agent. This results in a better homogeneity of the combination with thefollowing consequences elimination of fish-eye irregularities and improved uniformity in the ultimate color of the product.

Finally, the tests showed a third important property of glyceryl trimontanate, i.e., the transparency of the final product is substantially improved when such a product is colorless especially in the case where the initial mixture contains auxiliary agents. The transparency of the final product is improved with increasing amounts of glyceryl trimontanate up to 2 percent of the total mixture by weight.

Accordingly, the transparency of the final product used in Test II was better than that used in Test I and the transparency of the product used in Test III better than that of the product used in Tests 1 and I]. With regard to the transparency of the material used in Test lV, it is nearly perfectly transparent and ressembles a high quality glass.

The similar findings were made with regard to transparency of the material in the Tests V-Vlll.

Increasing the amount of glyceryl trimontanate beyond 2 percent of the total mixture by weight increases the time before which the material begins to stick to the cylinders but hardly has an effect on the which are stored in receptacles formed of a synthetic material which has been lubricated therewith.

in the abovementioned tests, the amount of glyceryl trimontanate was most often limited to 2 percent by weight because of legislation in France which limits the amount to this percentage. In practice systematic tests have been carried out with success between 0.1 and 3 percent of glyceryl trimontanate, these tests have confirmed the remarkable qualities of this product.

[claim l. Glyceryl trimontanate having the formula in which R is a linearly saturated hydrocarbon chain having 24 to 32 carbon atoms.

2. Glyceryl trimonanate as claimed in claim 1, whose hydroxyl number is between 10 and 15. 

2. Glyceryl trimonanate as claimed in claim 1, whose hydroxyl number is between 10 and
 15. 